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- 1. Top of the Class
High Performers in Science
in PISA 2006
Programme for International Student Assessment
- 2. ORGANISATION FOR ECONOMIC CO-OPERATION
AND DEVELOPMENT
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The OECD member countries are: Australia, Austria, Belgium, Canada, the Czech Republic,
Denmark, Finland, France, Germany, Greece, Hungary, Iceland, Ireland, Italy, Japan, Korea,
Luxembourg, Mexico, the Netherlands, New Zealand, Norway, Poland, Portugal, the Slovak Republic,
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- 3. Foreword
The rapidly growing demand for highly skilled workers has led to a global competition for talent. While
basic competencies are important for the absorption of new technologies, high-level skills are critical for
the creation of new knowledge, technologies and innovation. For countries near the technology frontier,
this implies that the share of highly educated workers in the labour force is an important determinant of
economic growth and social development. There is also mounting evidence that individuals with high level
skills generate relatively large externalities in knowledge creation and utilisation, compared to an “average”
individual, which in turn suggests that investing in excellence may benefit all. Educating for excellence is
thus an important policy goal.
When parents or policy-makers are asked to describe an excellent education, they often describe in fairly
abstract terms the presence of a rich curriculum with highly qualified teachers, outstanding school resources
and extensive educational opportunities. Nevertheless, excellent inputs to education provide no guarantee
for excellent outcomes. To address this, OECD’s Programme for International Student Assessment (PISA) has
taken an innovative approach to examining educational excellence, by directly measuring the academic
accomplishments and attitudes of students and to exploring how these relate to the characteristics of
individual students, schools and education systems. This report presents the results. Its development was
guided by three questions:
• Who are the students who meet the highest performance standards, using top performance as the criterion
for educational excellence? What types of families and communities do these students come from?
• What are the characteristics of the schools that they are attending? What kinds of instructional experiences
are provided to them in science? How often do they engage in science-related activities outside of
school?
• What motivations drive them in their study of science? What are their attitudes towards science and what
are their intentions regarding science careers?
The report shows that countries vary significantly in the proportion of students who demonstrate excellence
in science performance. Interestingly, scientific excellence is only weakly related to average performance
in countries, that is, while some countries show large proportions of both high and poor performers, other
countries combine large proportions of 15-year-olds reaching high levels of scientific excellence with few
students falling behind. Moreover, the talent pool of countries differs not just in its relative and absolute size,
but also in its composition. Student characteristics such as gender, origin, language, or socio-economic status
are related to top performance in science but none of these student characteristics impose an insurmountable
barrier to excellence. It is particularly encouraging that in some education systems significant proportions of
students with disadvantaged backgrounds achieve high levels of excellence, which suggests that there is no
inevitable trade-off between excellence and equity in education. There are lessons to be learnt from these
countries that may help improve excellence and equity in educational outcomes. The report shows that top
performers in science tend to be dedicated and engaged learners who aspire to a career in science but the
report also reveals that top performers often do not feel well informed about potential career opportunities
in science, which is an area school policy and practice can act upon. The link between attitudes and
Top of the class – High Performers in Science in PISA 2006 – ISBN 978-92-64-06068-5 – © OECD 2009
- 4. Foreword
motivations is strengthened by evidence suggesting that motivation among top performers is unrelated to
socio-economic factors but rather a reflection of their enjoyment and active engagement in science learning
inside and outside school. At the same time, in a number of countries there are significant proportions of top
performers who show comparatively low levels of interest in science. While these education systems have
succeeded in conveying scientific knowledge and competencies to students, they have been less successful
in engaging them in science-related issues and fostering their career aspirations in science. These countries
may thus not fully realise the potential of these students. Fostering interest and motivation in science thus
seems an important policy goal in its own right. The potential payoff seems worth this investment: a large
and diverse talent pool ready to take up the challenge of a career in science. In today’s global economy, it
is the opportunity to compete on innovation and technology.
The report is the product of a collaborative effort between the countries participating in PISA, the experts and
institutions working within the framework of the PISA Consortium, and the OECD. The report was drafted
by John Cresswell, Miyako Ikeda, Andreas Schleicher, Claire Shewbridge and Pablo Zoido. Henry Levin
provided important guidance in the initial stages of the report. The development of the report was steered
by the PISA Governing Board, which is chaired by Ryo Watanabe (Japan). The report is published on the
responsibility of the Secretary-General of the OECD.
Ryo Watanabe Barbara Ischinger
Chair of the PISA Governing Board Director for Education, OECD
Top of the class – High Performers in Science in PISA 2006 – ISBN 978-92-64-06068-5 – © OECD 2009
- 5. Table of contents
Foreword..................................................................................................................................................................................................................... 3
Executive Summary. ....................................................................................................................................................................................... 11
Reader’s guide...................................................................................................................................................................................................... 15
Chapter 1 Excellence in Science Performance............................................................................................................... 17
Introduction................................................................................................................................................................................................................... 18
The OECD Programme for International Student Assessment................................................................................................... 22
• Main features of PISA................................................................................................................................................................................... 22
• 2006 PISA assessment. ................................................................................................................................................................................ 23
• Definition of top performers in science........................................................................................................................................... 25
• Examples of tasks that top performers in science can typically do............................................................................... 27
Chapter 2 Students Who Excel........................................................................................................................................................ 35
Who are top performing students in science?....................................................................................................................................... 36
• Are top performers in science also top performers in mathematics and reading?.............................................. 36
• Are males and females equally represented among top performers?. ......................................................................... 37
• How well represented are students with an immigrant background among the top performers?............ 39
• Students’ socio-economic background............................................................................................................................................ 41
Which schools do top performers in science attend?...................................................................................................................... 44
• Are top performers in science in schools that only serve other top performers in science?......................... 44
• Differences in socio-economic background across schools.................................................................................................... 46
• Do top performers mainly attend schools that are privately managed?..................................................................... 47
• Do top performers mainly attend schools that select students based on their academic record?............ 50
Implications for educational policy and practice............................................................................................................................... 52
Chapter 3 Experiences, Attitudes and Motivations for Excellence.................................................... 53
How do top performers experience the teaching and learning of science?. ................................................................... 54
• Do top performers spend more time in school learning science?.................................................................................. 54
• Do top performers spend more time in science lessons outside of school?. .............................................................. 56
• How do top performers describe their science lessons?. ..................................................................................................... 56
• Do top performers pursue science-related activities?............................................................................................................. 58
Are top performers engaged and confident science learners?.................................................................................................. 60
• Which science topics are top performers interested in?....................................................................................................... 60
• Do top performers enjoy learning science?....................................................................................................................................... 61
• How important is it for top performers to do well in science........................................................................................... 62
• Are top performers confident learners?............................................................................................................................................ 64
Top of the class – High Performers in Science in PISA 2006 – ISBN 978-92-64-06068-5 – © OECD 2009
- 6. Table of contents
Are top performers interested in continuing with science?........................................................................................................ 66
• Do top performers perceive science to be of value?............................................................................................................... 66
• Do top performers intend to pursue science?.............................................................................................................................. 67
• Do top performers feel prepared for science-related careers?.......................................................................................... 68
• When top performers are relatively unmotivated, what are they like?. ...................................................................... 70
Implications for educational policy and practice............................................................................................................................... 74
References.................................................................................................................................................................................................................. 77
Appendix A Data tables............................................................................................................................................................................... 79
Appendix B Standard errors, significance tests and subgroup comparisons..................... 163
Top of the class – High Performers in Science in PISA 2006 – ISBN 978-92-64-06068-5 – © OECD 2009
- 7. Table of contents
List of Boxes
Box 1.1 Defining and comparing top performers in PISA..................................................................................................................26
Box 2.1 Comparing top performers with other students using PISA indices..............................................................................42
List of Figures
Figure 1.1 Top performers in science, reading and mathematics.........................................................................................................19
Figure 1.2 The global talent pool: a perspective from PISA....................................................................................................................21
Figure 1.3 Science top performers in PISA and countries’ research intensity.................................................................................22
Figure 1.4 A map of PISA countries and economies. ................................................................................................................................24
Figure 1.5 Acid Rain................................................................................................................................................................................................28
Figure 1.6 Greenhouse...........................................................................................................................................................................................30
Figure 2.1 Overlapping of top performers in science, reading and mathematics on average in the OECD. ....................36
Figure 2.2 Overlapping of top performers by gender................................................................................................................................38
Figure 2.3 Percentage difference of top performers by immigrant status..........................................................................................40
Figure 2.4 Percentage difference of top performers by language spoken at home.......................................................................41
Figure 2.5a Difference in socio-economic background between top performers and strong performers. ...................................42
Figure 2.5b Percentage of top performers with socio-economic background (ESCS) “below” or “equal to or above”
the OECD average of ESCS ..............................................................................................................................................................43
Figure 2.6 Percentage of students in schools with no top performers.....................................................................................................45
Figure 2.7 Relationship between socio-economic and performance differences between schools with top and
strong performers..................................................................................................................................................................................47
Figure 2.8 Top performers in public and private schools.........................................................................................................................49
Figure 2.9 Top performers, according to schools’ use of selecting students by their academic record...............................51
Figure 3.1a Regular science lessons in school, by performance group...............................................................................................54
Figure 3.1b Out-of-school science lessons, by performance group. .....................................................................................................55
Figure 3.2 Top and strong performers’ perception of the science teaching strategy focus on application. .......................57
Figure 3.3 Student science-related activities, by performance group. ...............................................................................................59
Figure 3.4 Enjoyment of science, by performance group........................................................................................................................62
Figure 3.5 Self-efficacy in science, by performance group.....................................................................................................................64
Figure 3.6 Future-oriented motivation to learn science, by performance group...........................................................................68
Figure 3.7a Proportion of relatively unmotivated top performers, by country..................................................................................70
Figure 3.7b Some characteristics of relatively unmotivated top performers, by country..............................................................71
List of Tables
Table 3.1 Interest in different science topics and enjoyment of science.........................................................................................61
Table 3.2 Instrumental motivation to learn science and the importance of doing well in science. ....................................63
Table 3.3 Self-concept in science.....................................................................................................................................................................65
Table 3.4 General and personal value of science.....................................................................................................................................66
Table 3.5 Motivation to use science in the future.....................................................................................................................................67
Table 3.6 Science-related careers: school preparation and student information.........................................................................69
Top of the class – High Performers in Science in PISA 2006 – ISBN 978-92-64-06068-5 – © OECD 2009
- 8. Table of contents
Table A1.1 Mean score and percentage of top performers in science, reading and mathematics..........................................80
Table A2.1a Overlapping of top performers in science, reading and mathematics.........................................................................81
Table A2.1b Overlapping of top performers in science, reading and mathematics, by gender..................................................82
Table A2.2 Percentage of students by performance group in science, reading and mathematics, by gender. ..................84
Table A2.3 Percentage of students by performance group, according to the immigrant status................................................87
Table A2.4 Percentage of students by performance group, according to the language spoken at home.............................89
Table A2.5a Students’ socio-economic background, by performance group.....................................................................................91
Table A2.5b Percentage of students with the PISA index of economic, social and cultural status (ESCS) lower than
the national average ESCS, by performance group...............................................................................................................92
Table A2.5c Percentage of students with the PISA index of economic, social and cultural status (ESCS) lower than
the OECD average ESCS, by performance group..................................................................................................................93
Table A2.6a Percentage of students in schools with no top performers................................................................................................94
Table A2.6b School average performance in science, by performance group...................................................................................95
Table A2.7 Average socio-economic background of school, by performance group...................................................................96
Table A2.8a Percentage of students by performance group, by school type.......................................................................................97
Table A2.8b Students’ socio-economic background in public and private schools...................................................................... 100
Table A2.9 Percentage of students by performance group, by schools’ use of selecting students
by their academic record.............................................................................................................................................................. 101
Table A3.1a Regular science lessons in school, by performance group............................................................................................ 103
Table A3.1b Out-of-school lessons in science, by performance group.............................................................................................. 104
Table A3.2a Science teaching strategy: focus on applications............................................................................................................... 105
Table A3.2b Science teaching strategy: hands-on activities.................................................................................................................... 106
Table A3.2c Science teaching strategy: interaction..................................................................................................................................... 107
Table A3.2d Science teaching strategy: student investigations............................................................................................................... 108
Table A3.3a Students’ science-related activities (mean index), by performance group.............................................................. 109
Table A3.3b Students’ science-related activities (underlying percentages), by performance group. ..................................... 110
Table A3.3c Parents’ report of students’ science activities at age 10 . ................................................................................................ 113
Table A3.4a General interest in science (mean index), by performance group.............................................................................. 114
Table A3.4b General interest in science (underlying percentages), by performance group...................................................... 115
Table A3.5a Enjoyment of science (mean index), by performance group......................................................................................... 119
Table A3.5b Enjoyment of science (underlying percentages), by performance group................................................................. 120
Table A3.6a Instrumental motivation to learn science (mean index), by performance group.................................................. 123
Table A3.6b Instrumental motivation to learn science (underlying percentages), by performance group.......................... 124
Table A3.7 Importance of doing well in science, mathematics and reading, by performance group................................ 127
Table A3.8a Self-efficacy in science (mean index), by performance group...................................................................................... 130
Table A3.8b Self-efficacy in science (underlying percentages), by performance group.............................................................. 131
Table A3.9a Self-concept in science (mean index), by performance group..................................................................................... 135
Table A3.9b Self-concept in science (underlying percentages), by performance group............................................................. 136
Table A3.10a General value of science (mean index), by performance group.................................................................................. 139
Table A3.10b General value of science (underlying percentages), by performance group.......................................................... 140
Table A3.11a Personal value of science (mean index), by performance group................................................................................. 143
Top of the class – High Performers in Science in PISA 2006 – ISBN 978-92-64-06068-5 – © OECD 2009
- 9. Table of contents
Table A3.11b Personal value of science (underlying percentages), by performance group......................................................... 144
Table A3.12a Future-oriented motivation to learn science (mean index), by performance group............................................ 147
Table A3.12b Future-oriented motivation to learn science (mean index) by performance group, by gender...................... 148
Table A3.12c Future-oriented motivation to learn science (underlying percentages), by performance group.................... 151
Table A3.13a School preparation of science-related careers (mean index), by performance group........................................ 153
Table A3.13b Future-oriented motivation to learn science (underlying percentages), by performance group.................... 154
Table A3.14a Student information on science-related careers (mean index), by performance group..................................... 156
Table A3.14b Student information on science-related careers (underlying percentages), by performance group........................ 157
Table A3.15 Proportion of relatively unmotivated top performers and their characteristics, by country............................. 159
Top of the class – High Performers in Science in PISA 2006 – ISBN 978-92-64-06068-5 – © OECD 2009
- 11. Executive Summary
This report looks at top-performing students in the PISA 2006 science assessment, their attitudes and
motivations, and the schools in which they are enrolled. Top-performers are defined as those 15-year-old
students who are proficient at Levels 5 and 6 on the PISA 2006 science scale as compared with strong
performers (proficient at Level 4), moderate performers (proficient at Levels 2 and 3), and those who are at
risk of being left behind (proficient at Level 1 or below).
Who are top performers in science in PISA 2006?
Top performers on the PISA 2006 science assessment form a diverse group, and the evidence suggests that
excellence in science can develop in very different educational settings and circumstances.
• Achieving excellence is not just a question of inherent student ability and it can also relate to specific
subject areas. The proportion of top performers varies widely from country to country. While, on
average, 9% of OECD students are top performers in science, 20% of all students in Finland and 18%
in New Zealand are top performers in science. On average across the OECD, 18% of students are top
performers in at least one of the subject areas of science, mathematics or reading. However, only 4% are
top performers in all three areas.
• A socio-economically disadvantaged background is not an insurmountable barrier to excellence. In
the typical OECD country about a quarter of top performers in science come from a socio-economic
background below the country’s average. Some systems, however, are even more conducive for students
from a relatively disadvantaged background to become top performers in science. For instance, in Japan,
Finland and Austria and the partner economies Macao-China and Hong Kong-China, a third or more of the
top performers in science come from a socio-economic background below the average of the country.
• Across subject areas and countries, female students are as likely to be top performers as male students.
On average across OECD countries, the proportion of top performers across subject areas is practically
equal between males and females: 4.1% of females and 3.9% of males are top performers in all three
subject areas and 17.3% of females and 18.6% of males are top performers in at least one subject
area. These averages, however, hide significant cross country variation and some significant gender gaps
across subject areas. While the gender gap among students who are top performers only in science is
small (1.1% of females and 1.5% of males), the gender gap is significant among top performers in reading
only (3.7% of females and 0.8% of males) and in mathematics (3.7% of females and 6.8% of males).
• Top performers in science tend to be non-immigrant students who speak the test language at home, but
in some countries immigrant or linguistic minority students excel as well. Germany, the Netherlands and
the partner country Slovenia are the countries where the largest differences, in favour of non-immigrant
students and students who speak the test language at home, are found.
Which schools do top performers in science attend?
The evidence from PISA suggests that some school characteristics, policies and practices matter for
excellence, and often in ways that interact with the socio-economic context of the schools.
11
Top of the class – High Performers in Science in PISA 2006 – ISBN 978-92-64-06068-5 – © OECD 2009
- 12. Executive Summary
• Top performers in science generally attend schools with student populations characterised by high
performance and a relatively advantaged socio-economic background. Many of these schools are
private. However, once student and school socio-economic background are accounted for the advantage
of private schools disappears in most OECD countries and in some countries it turns in favour of public
schools.
• Top performers in science generally attend schools characterised by certain school policies, such as
selecting in students according to their academic record, no ability grouping for all subjects or publishing
performance data publicly. Yet, perhaps due to specific system characteristics, such as tracking and
streaming, there is no consistent pattern across countries.
How do top performers in science experience science teaching and learning?
Learning experiences differ from one student to another. The analysis presented in this report shows that top
performers in science are engaged learners who put a significant amount of effort into the study of science,
particularly at school. They also actively engage in science-related activities outside school.
• In terms of effort, top performers in science spend more time studying science at school and less time
on out-of-school lessons. On average, top performers receive 4 hours of instruction in science at school,
half an hour more than strong performers and two hours more than lowest performers. By contrast
top performers receive on average 30 minutes of out-of-school lessons a week, whereas the lowest
performers receive 45 minutes, which may be attributable to the fact that these out-of-school lessons
are largely remedial in nature, rather than fostering scientific talent. Understanding the nature of out-
of-school lessons is important, as they are likely to differ across countries. Korea, a country with a large
proportion of top performers, is an important exception. Korean top performers take an hour more of
out-of-school lessons than lowest performers.
• Top performers in science are engaged science learners: they report that they enjoy learning science,
that they want to learn more, that their science lessons are fun and that they are motivated to do well in
science. On average 68% of top performers report being happy doing science problems (only 53% of
strong performers did so). Over 80% of top performers report that they enjoy acquiring new knowledge
in science, are interested in learning about science and generally have fun when learning science (only
50% of lowest performers did so).
• On top of what they do at school, top performers in science get involved in science-related activities
outside school. More than a third of top performers regularly or very often watch science programs on
TV and read science magazines or science articles in newspapers (only about 15% of lowest performers
report the same kind of behaviour). A somewhat smaller proportion of top performers regularly or very
often visit science-related websites (21%) or borrow or buy science books (14%). A few top performers
attend science clubs (7%) or listen to radio programs on science (5%). Even after accounting for socio-
economic background, top performers are significantly more involved in science-related activities than
strong performers (in all systems except the partner economy Chinese Taipei).
What attitudes and motivations towards science characterise top performers
in science?
Student attitudes and motivations tend to be closely related with student performance.
• Top performers in science care about doing well, in part because they believe that it will pay off in their
future academic and professional careers. 81% of top performers report they study science because it is
useful for them, 76% because it will improve their career prospects and 70% because they will need it
for what they want to study later on.
12
Top of the class – High Performers in Science in PISA 2006 – ISBN 978-92-64-06068-5 – © OECD 2009
- 13. Executive Summary
• In terms of their motivations, top performers in science report that they value their science learning.
More than three quarters of top performers (significantly more than any other group) believe they will
use science as adults, find it very relevant to themselves and expect to have many opportunities to use it
when they leave school.
• Top performers in science are confident learners. The average index of self-efficacy – a measure of
the student’s level of confidence in their own ability to handle specific scientific tasks effectively and
overcome difficulties – of top performers is 40% higher than that of strong performers. More than three
quarters of top performers (significantly more than strong performers) reported they can usually give
good answers to test questions on science topics, that they understand very well the science concepts
they are taught and that they learn science topics quickly. 70% of top performers and 55% of strong
performers reported science topics are easy for them.
Do top performers in science aspire to a career in science?
Top performers in science want to continue learning science but often do not feel well informed about
science-related careers.
• On average across the OECD, 56% of top performers report that they would like to study science after
secondary school. 61% of top performers report they would like to work in a career involving science.
• With respect to their aspirations, top performers in science report feeling well prepared for science-
related careers (more so than any other group). Across the OECD countries, for instance, top performers
agreed that the subjects they study (82%) and their teachers (81%) provide them with the basic skills and
knowledge for a science-related career.
• However, only around than half of top performers in science report being well informed about science-
related careers, or about where to find information on science related careers. Only a third of top
performers feel well informed about employers or companies that hire people to work in science-related
careers.
What do the findings tell us?
Countries vary significantly in the proportion of students who demonstrate excellence in science
performance. Interestingly, scientific excellence is only weakly related to average performance in
countries, that is, while some countries show large proportions of both high and poor performers, other
countries combine large proportions of 15-year-olds reaching high levels of scientific excellence with few
students falling behind.
The talent pool of countries differs not just in its relative and absolute size, but also in its composition.
Student characteristics such as gender, origin, language, or socio-economic status are related to top
performance in science but none of these student characteristics impose an insurmountable barrier to
excellence. It is particularly encouraging that in some education systems significant proportions of students
with disadvantaged backgrounds achieve high levels of excellence, which suggests that there is no inevitable
trade-off between excellence and equity in education.
As the individual socio-economic background of students relates to the prevalence of scientific excellence,
so does the socio-economic context in which schools operate. The interaction of this context with specific
school policies and practices also needs to be taken into consideration. For example, there are in general
higher proportions of top performers in private than in public schools. However, once the socio-economic
context of schools is accounted for, the edge for private schools disappears.
13
Top of the class – High Performers in Science in PISA 2006 – ISBN 978-92-64-06068-5 – © OECD 2009
- 14. Executive Summary
In terms of their experiences, attitudes, motivations and aspirations, top performers in science are dedicated
and engaged learners who aspire to a career in science. Top performers in science also tend to spend more
time in regular science lessons at school and more frequently engage in science related activities. They are
confident learners interested in a broad range of science topics, they enjoy learning science even when
the content is challenging and they believe they are good at science. They think that learning science will
prove useful for them in their further studies and professional activities and more often aspire to a career
in science, whether this is a cause or consequence of their performance and engagement with science.
However, top performers often do not feel well informed about potential career opportunities in science,
which is an area school policy and practice can act upon. The link between attitudes and motivations is
strengthened by evidence suggesting that motivation among top performers is unrelated to socio-economic
factors but rather a reflection of their enjoyment and active engagement in science learning inside and
outside school.
At the same time, in a number of countries there are significant proportions of top performers who show
comparatively low levels of interest in science. While these education systems have succeeded in conveying
scientific knowledge and competencies to students, they have been less successful in engaging them in
science-related issues and fostering their career aspirations in science. These countries may thus not fully
realise the potential of these students. Fostering interest and motivation in science thus seems an important
policy goal in its own right. Efforts to this end may relate to improved instructional techniques and a more
engaging learning environment at school but they can also extend to students’ lives outside school, such
as through establishing and making available more and better content on the internet or in video games
that applies scientific principles; establishing contests on the Internet with prizes for students who achieve
particular levels of performance or stages of accomplishment; more and better television programming
using children’s cartoons to enlist interests in science and scientific curiosity for younger children; or
science fiction novels and series of books on adventures or mysteries based upon scientific and technical
knowledge, ingenuity and solutions with characters.
In sum, educational excellence goes hand in hand with promoting student engagement and enjoyment of
science learning both inside and outside school. The payoff is quite significant: A large and diverse talent
pool ready to take up the challenge of a career in science. In today’s global economy, it is the opportunity
to compete on innovation and technology.
14
Top of the class – High Performers in Science in PISA 2006 – ISBN 978-92-64-06068-5 – © OECD 2009
- 15. Reader’s Guide
Data underlying the figures
The data referred to in Chapters 1 to 3 of this report are presented in Appendix A and, with additional
detail, on the PISA website (www.pisa.oecd.org). Five symbols are used to denote missing data:
a The category does not apply in the country concerned. Data are therefore missing.
c There are too few observations to provide reliable estimates (i.e. there are fewer than 30 students
or less than 3% of students for this cell or too few schools for valid inferences).
m Data are not available. These data were collected but subsequently removed from the publication
for technical reasons.
w Data have been withdrawn at the request of the country concerned.
x Data are included in another category or column of the table.
Calculation of international averages
An OECD average was calculated for most indicators presented in this report. In the case of some
indicators, a total representing the OECD area as a whole was also calculated:
• The OECD average corresponds to the arithmetic mean of the respective country estimates.
• The OECD total takes the OECD countries as a single entity, to which each country contributes
in proportion to the number of 15-year-olds enrolled in its schools. It illustrates how a country
compares with the OECD area as a whole.
In this publication, the OECD total is generally used when references are made to the overall
situation in the OECD area. Where the focus is on comparing performance across education
systems, the OECD average is used. In the case of some countries, data may not be available for
specific indicators, or specific categories may not apply. Readers should, therefore, keep in mind
that the terms OECD average and OECD total refer to the OECD countries included in the respective
comparisons.
Rounding of figures
Because of rounding, some figures in tables may not exactly add up to the totals. Totals, differences
and averages are always calculated on the basis of exact numbers and are rounded only after
calculation.
All standard errors in this publication have been rounded to two decimal places. Where the value
0.00 is shown, this does not imply that the standard error is zero, but that it is smaller than 0.005.
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- 16. Reader’s Guide
Reporting of student data
The report uses “15-year-olds” as shorthand for the PISA target population. PISA covers students
who are aged between 15 years 3 months and 16 years 2 months at the time of assessment and who
have completed at least 6 years of formal schooling, regardless of the type of institution in which
they are enrolled and of whether they are in full-time or part-time education, of whether they attend
academic or vocational programmes, and of whether they attend public or private schools or foreign
schools within the country.
Reporting of school data
The principals of the schools in which students were assessed provided information on their schools’
characteristics by completing a school questionnaire. Where responses from school principals are
presented in this publication, they are weighted so that they are proportionate to the number of
15-year-olds enrolled in the school.
Abbreviations used in this report
The following abbreviations are used in this report:
ISCED International Standard Classification of Education
SD Standard deviation
SE Standard error
Further documentation
For further information on the PISA assessment instruments and the methods used in PISA, see the
PISA 2006 Technical Report (OECD, 2009b) and the PISA website (www.pisa.oecd.org).
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- 17. 1
Excellence in
Science Performance
Introduction......................................................................................................................................................... 18
The OECD Programme for International Student Assessment........................................... 22
• Main features of PISA........................................................................................................................... 22
• 2006 PISA assessment. ........................................................................................................................ 23
• Definition of top performers in science................................................................................... 25
• Examples of tasks that top performers in science can typically do....................... 27
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Top of the class – High Performers in Science in PISA 2006 – ISBN 978-92-64-06068-5 – © OECD 2009
- 18. 1
Excellence in science performance
Introduction
The rapidly growing demand for highly skilled workers has led to global competition for talent (OECD,
2008). While basic competencies are generally considered important for the absorption of new
technologies, high-level competencies are critical for the creation of new knowledge, technologies and
innovation. For countries near the technology frontier, this implies that the share of highly educated
workers in the labour force is an important determinant of economic growth and social development.
There is also mounting evidence that individuals with high level skills generate relatively large amounts
of knowledge creation and ways of using it, compared to other individuals, which in turn suggests that
investing in excellence may benefit all (Minne et al., 2007).1 This happens, for example, because highly
skilled individuals create innovations in various areas (for example, organisation, marketing, design) that
benefit all or that boost technological progress at the frontier. Research has also shown that the effect
of the skill level one standard deviation above the mean in the International Adult Literacy Study on
economic growth is about six times larger than the effect of the skill level one standard deviation below
the mean (Hanushek and Woessmann, 2007).2
When parents or policy-makers are asked to describe an excellent education, they often describe in fairly
abstract terms the presence of a rich curriculum with highly qualified teachers, outstanding school resources
and extensive educational opportunities. Nevertheless, excellent inputs to science education provide no
guarantee for excellent outcomes. The approach to educational excellence in PISA is therefore to directly
measure the academic accomplishments and attitudes of students and to explore how these relate to the
characteristics of individual students, schools and education systems. From this perspective, the report
aims to identify the characteristics and educational situations of those students performing at top levels
of the PISA assessment and to compare them with the characteristics and situations of those with more
modest performance. Such comparisons might hint at potential policy interventions that could raise the
performance of all students.
The report looks specifically at top-performing students in the PISA 2006 science assessment, their learning
environment and at the schools in which they are enrolled. This report seeks to address the following
questions:
• Who are the students who meet the highest performance standards, using top performance as the criterion
for educational excellence? What types of families and communities do these students come from?
• What are the characteristics of the schools that they are attending? What kinds of instructional experiences
are provided to them in science? How often do they engage in science-related activities outside school?
• What motivations drive them in their study of science? What are their attitudes towards science and what
are their intentions regarding science careers?
Top-performers are defined as those students who are proficient at Levels 5 and 6 on the PISA 2006 science
scale, strong performers are proficient at Level 4, moderate performers are proficient at Levels 2 and 3, and
the lowest performers, those who are at risk, are only proficient at Level 1 or below. At age 15, top-performing
students can consistently identify, explain and apply scientific knowledge and knowledge about science
in a variety of complex life situations. They can link different information sources and explanations and
use evidence from those sources to justify decisions. They clearly and consistently demonstrate advanced
scientific thinking and reasoning, and they demonstrate use of their scientific understanding in support
of solutions to unfamiliar scientific and technological situations. Students at this level can use scientific
knowledge and develop arguments in support of recommendations and decisions that centre on personal,
social, or global situations.
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- 19. Percentage of top performers Percentage of top performers Percentage of top performers
0
5
10
15
20
25
30
35
0
5
10
15
20
25
30
35
0
5
10
15
20
25
30
35
Kyrgyzstan Indonesia Azerbaijan
Jordan Kyrgyzstan Kyrgyzstan
Colombia Azerbaijan Indonesia
Indonesia Tunisia Tunisia
Tunisia Jordan Colombia
Qatar Thailand Mexico
Mexico Serbia Montenegro
Montenegro Romania Qatar
Azerbaijan Montenegro Thailand
Brazil Mexico Argentina
Argentina Qatar Romania
Romania Colombia Brazil
Thailand Argentina Jordan
Chile Brazil Serbia
Serbia Russian Federation Turkey
Bulgaria Spain Uruguay
Uruguay Bulgaria Chile
Turkey Turkey Bulgaria
Croatia Macao-China Portugal
Greece Uruguay Greece
Portugal Greece Latvia
Source: OECD PISA 2006 Database, Table A1.1.
Israel Chile Russian Federation
Italy Croatia Italy
Latvia Lithuania Spain
Spain Latvia Lithuania
Russian Federation Portugal Croatia
United States Hungary Israel
Lithuania Chinese Taipei Macao-China
Level 5
Level 5
Ireland Israel Slovak Republic
Hungary Italy Luxembourg
Figure 1.1
Norway Slovenia Norway
Level 5
Luxembourg Slovak Republic Iceland
Poland Luxembourg Poland
Slovak Republic Denmark Denmark
Level 6
Level 6
United Kingdom Iceland Hungary
Top performers in science
France Estonia Top performers in reading Sweden
Estonia France France
Top performers in mathematics
Sweden Norway OECD average
Iceland Switzerland United States
OECD average OECD average Ireland
Slovenia Austria Austria
Denmark United Kingdom Belgium
Germany Netherlands Korea
Top performers in science, reading and mathematics
Austria Czech Republic Switzerland
Australia Japan Estonia
Macao-China Liechtenstein Czech Republic
Canada Germany Germany
Czech Republic Australia Liechtenstein
Countries are ranked in ascending order of the percentage of top performers in each domain of assessment.
Japan Sweden Slovenia
Liechtenstein Belgium Netherlands
New Zealand Poland United Kingdom
Netherlands Ireland Canada
Belgium Hong Kong-China Australia
Switzerland Canada Chinese Taipei
Finland New Zealand Japan
Korea Finland Hong Kong-China
Hong Kong-China Korea New Zealand
Top of the class – High Performers in Science in PISA 2006 – ISBN 978-92-64-06068-5 – © OECD 2009
Excellence in science performance
Chinese Taipei Finland
1
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- 20. 1
Excellence in science performance
The proportion of top performers in science varies widely across countries. Figure 1.1 shows the
proportions of top performers for each country in science, reading and mathematics. Although on average
across OECD countries, 9% of 15-year-olds reach Level 5 in science, and slightly more than 1% reach
Level 6, these proportions vary substantially across countries. For example, among the OECD countries,
seven have at least 13% of top performers in science, whereas there are six with 5% or less. Among the
partner countries and economies the overall proportions of these top performers also vary considerably
from country-to-country with many countries almost absent from representation at Level 6 in science.
Similar variability is shown in reading and mathematics with only slight differences in the patterns of
these results among countries.
It is noteworthy that the share of 15-year-olds who are top performers in science is distributed unevenly
across countries. Of the 57 countries, nearly one-half (25) have 5% or fewer (based on a round percentage)
of their 15-year-olds reaching Level 5 or Level 6, whereas four countries have at least 15% – i.e. three times
as many – with high science proficiency [See Table 2.1a and Table 2.1c, PISA 2006: Science Competencies
For Tomorrow’s World (OECD, 2007)]. However, the variability in percentages in each country with high
science proficiency suggests a difference in countries’ abilities to staff future knowledge-driven industries
with home-grown talent.3 Among countries with similar mean scores in PISA there is a remarkable diversity
in the percentage of top-performing students. For example, France has a mean score of 495 points in science
in PISA 2006 and a proportion of 8% of students at high proficiency levels in science (both very close to
the OECD average), Latvia is also close to the OECD average in science with 490 points but has only 4% of
students at high proficiency, which is less than half the OECD average of 9%. Although Latvia has a small
percentage of students at the lowest levels, the result could indicate the relative lack of a highly educated
talent pool for the future.
Despite similarities across countries for each subject area, a high rank in one is no guarantee for a high
rank in the others. The cross country correlation among these measures is above 0.8 but the definition
of top performance is subject area specific and therefore any comparison across subject areas should
be interpreted with caution. It is possible however to compare the relative position of countries when
compared with others in each subject area. For instance, Ireland is in the top 10% of the distribution
of reading top performers across countries but it is in the bottom half of the distribution of mathematics
top performers. The partner economy Chinese Taipei for example is in the top 10% of the distribution of
mathematics and top performers in science across countries but in the bottom half of the distribution for
reading top performers.
These results highlight the need for a rigorous analysis of excellence patterns across countries. The high
variance across countries in the proportion of top performers in science shows that some educational
systems give rise to higher proportions of high competency students than others. The differences across
subject areas show that different educational experiences result in different types of top performers. The
following chapters of this report are devoted to understanding better why educational systems result in
different proportions of top performers in science, what characteristics these students have, what schools
they tend to attend, how they experience teaching and learning science, their attitudes towards science and
their motivations and aspirations for science learning in their future careers.
Figure 1.2 depicts the number of 15-year-old students proficient at Levels 5 and 6 on the PISA science
scale by country. Both the proportion of top performers within a country and the size of countries matter
when establishing the contribution of countries to the global talent pool: even though the proportion of top
performers in science is comparatively low in the United States, the United States takes up a quarter of the
pie shown in Figure 1.2, simply because of the size of the country. In contrast Finland, that educates the
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Top of the class – High Performers in Science in PISA 2006 – ISBN 978-92-64-06068-5 – © OECD 2009